Classifications

• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06F—ELECTRIC DIGITAL DATA PROCESSING
  • G06F11/00—Error detection; Error correction; Monitoring
  • G06F11/07—Responding to the occurrence of a fault, e.g. fault tolerance
  • G06F11/14—Error detection or correction of the data by redundancy in operation
  • G06F11/1402—Saving, restoring, recovering or retrying
  • G06F11/1415—Saving, restoring, recovering or retrying at system level
  • G06F11/1417—Boot up procedures
• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06F—ELECTRIC DIGITAL DATA PROCESSING
  • G06F11/00—Error detection; Error correction; Monitoring
  • G06F11/07—Responding to the occurrence of a fault, e.g. fault tolerance
  • G06F11/14—Error detection or correction of the data by redundancy in operation
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
  • H04L12/00—Data switching networks
  • H04L12/28—Data switching networks characterised by path configuration, e.g. LAN [Local Area Networks] or WAN [Wide Area Networks]

Definitions

• Stand-alone networking equipment such as a DSL modem, a bridge or a router or a combination thereof, is used for example to interface a local area network with an access network such as the Internet.
• stand alone equipment comprise a persistent memory, also called on board memory means, such as a read only memory (ROM) and/or an electrically erasable programmable read only memory (EEPROM).
• ROM read only memory
• EEPROM electrically erasable programmable read only memory
• some stand alone equipments contain two copies of some of the items mentioned above i.e. the equipment configuration, the boot software and the firmware.
• some modems may have a persistent memory just large enough to contain a single copy of these data. In that case, if these data are corrupted, the equipment ceases functioning properly until the persistent memory recovers a new valid firmware or configuration or boot program. This situation might occur, for example, when the modem downloads upgraded software from an appropriate server. As the persistent memory can hold only one copy of the software, the old software is erased before the updated one is fully recorded. If the connection is cut off or if the equipment is powered down during the download, the software is corrupted.
• the present invention proposes a network equipment for connection to a local network, said network comprising at least one software server, said equipment comprising a persistent memory for storing software, characterized in that it comprises : - communication means for connection to said network, - means for monitoring the start up of the equipment in order to detect a software failure, - means for generating a software failure signal in response to the detection of a failure by the monitoring means, and for automatically sending a notification of the failure on the network, wherein said notification is broadcast on the network for reception by said at least one software server.
• the server comprises an application for analysing the failure type and for automatically taking corrective actions.
• the means for generating a failure signal are adapted to requesting the automatic download of replacement software in the memory means from the software server.
• this embodiment's persistent memory needs to hold only one software copy and has the same level of robustness as an equipment holding two copies of the software or data.
• the software download is done without any delay.
• the present invention also proposes a method for monitoring the software start up of a network equipment, the equipment comprising a persistent memory for storing software and communication means for connection to a network comprising at least one software server, this process comprising the steps of: - monitoring the software start up of the equipment in order to detect a software start up failure, - generating a software start up failure signal in response to the detection of a start up software failure, - automatically broadcasting the software failure signal on the network for reception by said at least one software server.
• FIG. 1 shows a block diagram of a system encompassing the network equipment according to the present embodiment
• - Figure 2 depicts schematically a flow diagram of a processing method suitable for use in the system of figure 1 and in accordance with the principles of the present embodiment
• - Figure 3 depicts schematically a flow diagram of the method illustrated in figure 2 with more details.
• Figure 1 shows a block diagram of a system incorporating a standalone equipment 1 according to the present invention.
• This network equipment 1 consists in any device able to process data transfer communication. It can be, for example, a DSL type modem or another stand-alone networking equipment.
• the equipment is connected to a local area network 2, to which is also connected a server 3 and/or a device with a failure processing application (not shown).
• the network equipment 1 is provided with persistent on board memory means 4 such as an Electrically Erasable Programmable Read Only Memory (EEPROM).
• EEPROM Electrically Erasable Programmable Read Only Memory
• This persistent memory holds a plurality of items. According to the present embodiment, it stores among others data and software programs necessary for the start up and functioning of the equipment: e.g. equipment configuration parameters 5, a boot software 6 and a firmware 7.
• the equipment configuration 5 is a set of parameters containing among others the serial number and the network address of the modem.
• Firmware 7 consists in any software written in a memory that is not erasable by an application level software, i.e. which has a certain protection.
• firmware comprises e.g. the modem's operating system.
• the firmware may be replace globally by a download, the firmware may comprise distinct items, and the invention is not limited to a bulk download but also extends to testing and downloading separate items.
• the stand-alone equipment 1 comprises also a data processing unit such as a microprocessor running the different programs and a non-persistent memory, not represented for clarity reason. Prior to execution, software stored in the persistent memory is copied to the non-persistent memory (e.g. RAM).
• the stand-alone equipment comprises also a data transfer module 8 between the on board memory means 4 and network communication means 9 connected to the network 2.
• This transfer module 8 can employ for example the standardized Bootstrap protocol (BOOTP), and the file transfer protocol (TFTP) to exchange information between the server 3 and the equipment 1 via the local area network 2.
• the equipment being a DSL modem according to the present embodiment, it also comprises a corresponding PSTN interface and associated circuitry to carry out its DSL functionalities. These items are well known in themselves and not represented in figure 1.
• Modules 8 and 10 may either be hardware implemented or be software modules run by the microprocessor from the non-persistent memory.
• the stand-alone equipment 1 comprises also monitoring means 10 able to control the start up of the software of the equipment. These monitoring means 10 check, among other things, validity, presence and correct start up of the firmware 7 and the validity of the configuration data 5.
• these monitoring means 10 generate a firmware start up failure signal which is transmitted by the transfer module 8 and the communication means 9 through the data transfer network 2 to the software server 3.
• This failure signal notified to the software server 3, is associated to a BOOTP request of downloading of replacement firmware by the server.
• a frame portion of the BOOTP protocol used for sending this failure signal specifies the kind of software to be downloaded or the appropriate failure signal. This frame portion can be, for instance, the "vendor specific optional field" of the BOOTP protocol.
• an application in the data transfer network 2 illustratively the software server 3, maintains a data base wherein program codes and replacement software and/or configuration data are stored.
• this server 3 transmits replacement software to the network equipment, through the network 2, using the TFTP protocol of the transfer module 8 and the communication means 9.
• the BOOTP message comprises a number of failure states of the equipment, following the process detailed below. Another device on the local area network will interpret these states and decide on a corrective action, typically including a replacement software download, but may also include notifying failure information to a user.
• the monitoring means 8 can also be associated to a button 11 which can be operated manually by the user to trigger the request of a firmware and/or boot software download over the network.
• FIG. 2 shows a flow diagram which illustrates a simplified version of the start up process of the stand alone equipment 1 according to the present embodiment. The shown steps relate mainly to testing the validity and presence a software like for example a firmware in memory 4.
• monitoring means 10 launch a firmware testing step 21 concerning the firmware necessary to start up the equipment 1. If no problem is detected during this testing step, monitoring means 10 check, in step 22, if the firmware is stored in the on board memory means 4. If the firmware is missing, the monitoring means 10 generate a software start up failure signal F, and reboot the equipment 1.
• the monitoring means 10 request the downloading of a replacement firmware from the software server 3 through the transfer network 2 by using the BOOTP protocol of the transfer module 8 and the communication means 9.
• the software server 3 downloads a replacement firmware through the transfer network 2 by using the TFTP protocol of the transfer module 8 and the communication means 9.
• the monitoring means 10 control the correctness of the downloading.
• the monitoring means 10 generate a specific firmware failure signal F (comprising the identification of the failure type), and reboot the equipment 1 so that a new download may be initiated. If the tests are correctly performed, the monitoring means 10 load, during step 26, the firmware and set a start up failure flag and a timer to determine a start up time limit.
• the flag is reset by the firmware if it performs its start up properly. If the software start up is not completed once the start up time limit is reached, the flag is still set, and the monitoring means 10 generate a software start up failure signal F (also comprising an identification of the failure type, different from the first failure type above), and reboot the equipment 1. Otherwise, at step 27, when the software start up is properly executed it resets the software start up flag and no failure signal is generated.
• the network equipment comprises
• the block diagram of figure 3 shows the details of the start up process of the stand alone equipment according to the embodiment.
• the process begins at step 30, when a power on condition is initiated for the network equipment.
• the process of figure 3 is then executed by the monitoring means 10, using the well known BOOTP and TFTP protocols.
• initial tests are executed.
• the monitoring means 10 check the availability of the persistent memory 4 and the proper operation of the non persistent memory.
• Equipment configurations 5 are often secured by a signature or a checksum. This signature or checksum is registered in the on board memory means 4 of the equipment 1.
• a classical and easy way to control the validity of an equipment configuration consists in recalculating its checksum and comparing it to the registered one. If there is a mismatch, the equipment configuration 5 is no more valid. In that case, the monitoring means 10 set up a corresponding failure flag 34.
• this flag 34 is encoded to deliver information about the type of failures encountered.
• the failure flag 34 comprises an information status indicating the presence of an equipment configuration failure.
• the configuration data failure may or may not be correctable through a download.
• the BOOTP message issued by the equipment is interpreted by other network devices as indicating that the equipment cannot be used any more and is to be considered as dead.
• the monitoring means 10 set also a software start up failure flag 35. This failure flag 35 specifies that the user has requested a firmware download.
• the monitoring means 10 check, after step 32, the validity of the firmware program 7 registered in the on board memory means 4 during step 36.
• a simple way to do that consists in controlling the presence and the validity of its verification pattern (FVP for Flash Verification Pattern).
• the verification pattern is a classical tool for checking the integrity of software or data.
• a verification pattern is calculated and also written into memory 4. Should the equipment suffer a power failure or another problem during the storage of the firmware, the verification pattern corresponding to this firmware is either not stored or wrong. Therefore, at step 36, the monitoring means 10 check the validity of the firmware with the help of the firmware verification pattern. If the pattern is not valid, then a failure flag 37 is set.
• this particular failure flag indicates the nature of the failure.
• the monitoring means 10 check the setting of the failure flags 34, 35, 37. If at least one flag is set, the monitoring means 10 will automatically send a failure signal to the server 3 through the transfer network 2 using the BOOTP protocol of the transfer module 8 and the communication means 9. This message contains the failure flag state.
• Applications bundled with network devices such as an application of the software server 3, listen for these signals and interpret the failure status information. After interpretation of this information, these applications decide, preferably without any end user intervention, on an action comprising at least one of starting a firmware download to the network equipment 1 and/or notifying the problem to the user. e.g.
• the transfer module 8 indicates the problem status in the "vendor optional specific field" of an appropriate BOOTP protocol message sent on the network by the monitoring means 10. This field is of standard use to communicate to an application certain restrictions or additional client information. In other words, the message is preferably broadcast on the network and not specifically to a predetermined server.
• any one of the devices on the network may act as a server provided it has the right application to listen to, analyze and respond to the message.
• the replacement software is stored in the persistent on board memory means 4.
• This step has reference 39.
• the monitoring means 10 control that the replacement software has been downloaded without any interruption and that it has been correctly recorded.
• the software downloaded is a firmware
• the data processing unit checks the replacement firmware and calculates its flash verification pattern (FVP) and records it in the memory 4 at step 41. If the replacement software is damaged or incorrectly downloaded or recorded, the monitoring means 10 sets a corresponding failure flag 42. Then, the stand alone equipment 1 is rebooted.
• the flags are stored in such a way as to be unaffected by the rebooting process.
• the device tests whether flag 42 is set and sends a corresponding BOOTP message to request a firmware download.
• the monitoring means 10 control the presence of the firmware in the on board memory means 4. There are different methods available for checking this presence. For instance, the firmware's presence can be checked with the detection of a specified identification code in a fixed location of the firmware code. Other methods can also be used in accordance with this invention. If no software is registered, the monitoring means 10 set a failure flag
• step 44 and the modem is rebooted at step 30 to process the failure based on the set flag as above.
• the monitoring means 10 set a start up flag and trigger a start timer, at step 45, before loading and starting the firmware at step 46. After a successful start up, the start up flag is reset by the firmware, confirming that it started properly. However, if the start up is not performed before the start time has elapsed, the monitoring means 10 set a problem flag 48 and reboot the equipment at step 30 to process the corresponding failure.
• the process of figure 3 defines five problem states : - software (firmware) start-up error: the firmware either halts during start-up or reboots without correctly starting up; - invalid configuration ; - failed software (firmware) download (e.g; interruption of download process) ; - absence of software ; - writing of downloaded software to persistent memory failed verification pattern incorrect).
• Other states may trigger a download of software : - a mechanical button of the device was pressed by the user to request a firmware download ; - the firmware received a request over the network to perform a firmware update. Flags are checked by the monitoring means either at the beginning of the boot process, or during its execution.
• a download can be requested explicitly, or the decision as to a download should be left to an application listening to the device's messages.
• This invention is not restricted to the preferred embodiment herewith disclosed.
• any kind of software or data can be downloaded. And this process can also be performed with protocols differing from the TFTP and BOOTP protocols.

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• Engineering & Computer Science (AREA)
• Theoretical Computer Science (AREA)
• General Physics & Mathematics (AREA)
• Quality & Reliability (AREA)
• Physics & Mathematics (AREA)
• General Engineering & Computer Science (AREA)
• Signal Processing (AREA)
• Computer Networks & Wireless Communication (AREA)
• Stored Programmes (AREA)
• Information Transfer Between Computers (AREA)
• Debugging And Monitoring (AREA)
• Small-Scale Networks (AREA)
• Test And Diagnosis Of Digital Computers (AREA)

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• 2003
  • 2003-06-30 EP EP03447177A patent/EP1494119A1/en not_active Withdrawn
• 2004
  • 2004-06-25 CN CNB2004800174934A patent/CN100419698C/zh not_active Expired - Fee Related
  • 2004-06-25 JP JP2006516075A patent/JP4680896B2/ja not_active Expired - Fee Related
  • 2004-06-25 EP EP04740376.1A patent/EP1639468B1/en not_active Expired - Fee Related
  • 2004-06-25 BR BRPI0412151-1A patent/BRPI0412151A/pt not_active Application Discontinuation
  • 2004-06-25 KR KR1020057024701A patent/KR101082940B1/ko active IP Right Grant
  • 2004-06-25 US US10/561,142 patent/US7805637B2/en not_active Expired - Fee Related
  • 2004-06-25 WO PCT/EP2004/006976 patent/WO2005003974A2/en active Application Filing
  • 2004-06-25 MX MXPA05014131A patent/MXPA05014131A/es active IP Right Grant

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